KR102250319B1 - Valve for mixing two gas streams - Google Patents

Abstract

The present invention is a valve (1) for mixing two gas streams, comprising a housing (11), a first gas inlet (2), a second gas inlet (3), and a gas outlet (4), the gas The inlet (2, 3) is fluidly connected to the gas outlet (4), and downstream of the first gas inlet (2) is arranged a guide element (5) displaceably mounted in the housing (11). And, by displacing the guide element 5, the flow cross section of the flow delivery opening 6 for flow delivery of the gas volume flowing through the first gas inlet 2 to the gas outlet 4 is It relates to the valve (1), which can be adjusted via the guiding element (5).

Description

Valve for mixing two gas streams

The present invention relates to a valve for mixing two gas streams, comprising a housing, a first gas inlet, a second gas inlet and a gas outlet, wherein the gas inlets are fluidly connected to the gas outlet. will be.

Valves are used, for example, to mix two gas streams in an exhaust gas recirculation system. Among known designs are valves that include a rotatable throttle flap, which can be rotated by an electric motor, a simple pneumatic on/off valve or an electromagnetically operated valve.

All of these known valves have a complex structure in common and have the problem of being expensive, or not being able to perform sufficiently accurate control between a fully open state and a fully closed state when providing control.

Accordingly, the problem solved by the present invention is to create a valve that has a simple structure and is capable of reliably mixing two gas streams in any desired ratio.

This task is achieved with a valve having the features of claim 1 in connection with the valve.

An exemplary embodiment of the present invention is a valve for mixing two gas streams, comprising a housing, a first gas inlet, a second gas inlet, and a gas outlet, the gas inlets allowing fluid flow to the gas outlet. Connected, and a guide element displaceably mounted in the housing is disposed downstream of the first gas inlet, and by displacing the guide element, a gas volume introduced through the first gas inlet is transferred to the gas outlet. It relates to the valve, wherein the flow cross section of the flow delivery opening for flow delivery can be controlled via the guiding element.

The guiding element is formed in such a way that a gas stream entering from the first gas inlet can flow therethrough. The flow of gas around the guiding element is prevented by a precise guiding or sealing element in the housing. The guiding element is movably mounted in the housing so as to be able to displace the guiding element by applying a force to the guiding element. The movement of the guiding element opens the flow cross section of the guiding element, for example an opening, so that a gas stream coming from the first gas inlet can flow through the guiding element to the gas outlet.

It is particularly advantageous that, by means of the guiding element, it is possible to control the flow cross section for flow transfer of the gas volume entering through the second gas inlet to the gas outlet. This is particularly advantageous as it is possible to affect both the gas stream from the first gas inlet and the gas stream from the second gas inlet using a single guiding element. This can be advantageously realized, for example, by sliding the guiding element into a flow path downstream of the second gas inlet, thereby at least partially blocking the flow path. As a result, the mass flow is reduced. In the extreme position, the guiding element can also completely block the flow path from the second gas inlet to the gas outlet and allow gas flow from the first gas inlet to the gas outlet. This function can selectively flow gas from the first gas inlet or gas from the second gas inlet stream to the gas outlet, or the gas stream consisting of two gas streams at any desired ratio. You can let it flow to the exit.

The guiding element is of a sleeve-like design, and it is also advantageous to close the flow path downstream of the first gas inlet in a completely fluid tight manner. The sleeve-like guide element can be mounted in a particularly simple manner in the tubular housing section and can be displaced relative to the section. Moreover, the sleeve forming the flow delivery opening is particularly simple to manufacture.

A preferred exemplary embodiment is characterized in that the guiding element has the flow transmission opening in its radial edge region. It is particularly advantageous for the guiding element to have a flow transfer opening in the radial wall area, as at least one position of the guiding element is in contact with the inner wall of the flow path downstream of the first gas inlet. . In this position, gas flow transfer from the first gas inlet is prevented. When the guide element is correspondingly displaced to such an extent that the flow delivery opening protrudes beyond the first gas inlet and into a valve region that is no longer closed by an inner wall of the flow path, the gas stream It can flow through the guiding element, in particular through the flow delivery opening, to the gas outlet.

Downstream of the first gas inlet there is a first flow path through which the guiding element can be displaced, the guiding element in a second flow path downstream of the second gas inlet and/or upstream of the gas outlet. It is also preferred that it can be moved at least partially in the third flow path in the.

The movement of the guiding element in the second flow path or in the third flow path means that the flow delivery opening is no longer completely covered by the inner wall of the first flow path or is no longer covered by the gas stream. It ensures that it can flow through the guiding element.

Furthermore, the housing has a T-shaped cross section, but the first leg forms the first flow path, the second leg forms the second flow path, and the third leg forms a first flow path toward the gas outlet. It is advantageous to form 3 flow paths. In this case, the T-shape is particularly advantageous because the flow paths downstream of the gas inlet or upstream of the gas outlet create a mixing position in a simple manner by intersecting each other. Moreover, guiding elements protruding from one flow path to the mixing position may affect the flow cross section of another flow path.

Furthermore, it is advantageous that the flow transfer opening is closed by a wall defining the first flow path, as long as the guiding element does not protrude far enough into the second or third flow path. This is advantageous in order to be able to realize closing or opening the flow delivery opening only by displacing the guiding element into the first flow path.

Further, the valve, in a first position, allows a delivery flow of a gas volume from the first gas inlet, a delivery flow of a gas volume from the second gas inlet to the gas outlet, and from the first gas inlet The delivery flow of the gas volume of is controlled by the open cross-sectional area of the flow delivery opening, and the delivery flow of the gas volume from the second gas inlet is unobstructed by the sleeve-shaped guiding element and/or the second flow path. Or it is advantageous if it is controlled by the cross-sectional area of the third flow path. By sliding the guiding element into the second flow path and/or the third flow path, the flow cross section of the flow path can be reduced, thereby affecting the amount of gas flowing through each flow path. In the extreme position, it is also possible to completely close one of the two flow paths into which the guiding element slides in.

It is further advantageous that at least one sealing means is provided between the sleeve-like guiding element and the wall defining the first flow path so that it is prevented from flowing around the guiding element. This is advantageous to avoid undesired gas flowing from the first gas inlet to the gas outlet.

Furthermore, an actuator disposed outside the housing acts on the guiding element, and transmitting a force from the actuator to the guiding element is carried out by a guiding rod, the guiding rod being the second flow path and/or the third It is advantageously connected to the guiding element protruding through the flow path and distal to the first gas inlet. The actuator may be, for example, a stepper motor or other electric motor capable of translating the guiding element in the first flow path.

It is also advantageous that the guiding element comprises a guiding structure therein which directs the gas stream flowing to the guiding element to the flow delivery opening. Particularly advantageously, the guiding element has an inner shape that directs the gas stream going from the inlet to the guiding element to the flow delivery opening. This makes it possible to avoid additional pressure losses due to the guiding element.

Advantageous improvements of the invention are set forth in the following description in connection with the dependent claims and the drawings.

The invention will be discussed in detail below on the basis of exemplary embodiments and with reference to the drawings.
1 is a schematic cross-sectional view of a valve according to the invention;
Fig. 2 is a cross-sectional view through a valve according to the invention, showing the location of a guiding element preventing flow transfer from a first gas inlet to a gas outlet;
Fig. 3 is a cross-sectional view corresponding to Fig. 2, showing the displacement of the guiding element in a manner that allows flow transfer from a first gas inlet through a flow transfer opening to a gas outlet.

1 shows a schematic view of a valve 1 comprising a first gas inlet 2, a second gas inlet 3 and a gas outlet 4. The gas inlets 2 and 3 are fluidly connected to the gas outlet 4. Downstream of the gas inlet 2 is a guiding element 5 formed as a sleeve and completely closing the first flow path. The guiding element 5 has a flow transmission opening 6 in the radial wall, which flow transmission opening is covered by the inner wall of the first flow path.

The gas can be introduced through the gas inlets 2 and 3 along the arrows 8 and 9, and can flow out from the gas outlet 4 along the arrow 10 after being mixed.

The guiding element 5 is connected via a guiding rod 7 to an actuator (not shown) outside the housing 11 of the valve 1 and can be translated by the actuator along a first flow path.

As can already be seen in the schematic diagram of FIG. 1, in the first position of the guiding element 5 the flow transmission opening 6 is completely covered by a wall defining the first flow path, thus closing the flow transmission opening 6. It is effectively prevented from flowing through.

If the guide element 5 is displaced far enough to the left, the flow delivery opening 6 is opened so that flow delivery to the gas outlet 4 can take place. Depending on the length of the movement, the flow delivery opening 6 can be partially or completely open, thereby controlling the amount of gas actually delivered.

2 and 3 that follow show possible improvements of the valve 1 corresponding to the schematic diagram of FIG. 1. Reference signs to the same parts are maintained to facilitate understanding.

FIG. 2 shows a side cross-sectional view of the valve 1 shown in FIG. 1. On the left side of the housing 11 an actuator 12 used to move the guiding element 5 is shown.

The flow paths downstream of the gas inlets 2 and 3 and upstream of the gas outlet 4 are formed in a tubular shape and intersect each other in common. In FIG. 2, the guiding element 5 is fully positioned in the first flow path and closes the flow delivery opening 6. Thus, the gas inlet 2 is completely blocked, whereby only the gas coming from the second gas inlet 3 can flow to the gas outlet 4.

By retracting the guide element 5 to the mixing point, the active flow cross section of the second flow path downstream of the second gas inlet 3 is reduced. At the same time, the flow delivery opening 6 is at least partially open so that a gas stream coming from the first gas inlet 2 can also flow to the gas outlet 4.

FIG. 3 shows the valve 1 of FIG. 2, wherein the guiding element 5 of FIG. 3 is displaced in a second flow path, whereby the flow transmission opening 6 is at least partially opened. At the same time, the flow cross section downstream of the second gas inlet 3 is reduced.

In the position shown in FIG. 3, a gas stream coming from the two gas inlets 2, 3 can flow to the gas outlet 4. According to the open cross-section of the flow delivery opening 6 and the unobstructed flow cross-section of the second flow path, a mixture of two gas streams is produced.

The exemplary embodiments of FIGS. 1 to 3 are not particularly intended to limit the invention, but to illustrate the concept of the invention.

Claims (11)

As a valve (1) for mixing two gas streams,
Including a housing 11, a first gas inlet 2, a second gas inlet 3, and a gas outlet 4,
The gas inlet (2, 3) is fluidly connected to the gas outlet (4), and downstream of the first gas inlet (2) a guide element (5) displaceably mounted in the housing (11) Is arranged and, by displacing the guiding element 5, the flow of the flow delivery opening 6 for flow delivery of the gas volume entering through the first gas inlet 2 to the gas outlet 4 The cross section can be controlled via the guiding element 5,
The guiding element 5 is formed in such a way that a gas stream entering from the first gas inlet 2 can flow through,
The guiding element 5 has the flow transmission opening 6 in the region of the radial edge of the guiding element 5,
Valve (1), characterized in that in at least one position of the guiding element (5) a radial wall area contacts the inner wall of the flow path downstream of the first gas inlet (2). The flow cross section according to claim 1, characterized in that by means of the guiding element (5) it is possible to control the flow cross section for flow transfer of the volume of gas flowing through the second gas inlet (3) to the gas outlet (4). Valve (1). 3. The flow path according to claim 1 or 2, wherein the guiding element (5) is of a sleeve-like design and closed in a completely fluid tight manner downstream of the first gas inlet (2). Valve (1), characterized in that. 3. Valve (1) according to claim 1 or 2, characterized in that the guiding element (5) has the flow transmission opening (6) in its radial edge region. 3. A first flow path according to claim 1 or 2, wherein downstream of the first gas inlet (2) there is a first flow path through which the guiding element (5) can be displaced, the guiding element (5) being the second Valve (1), characterized in that it can be moved at least partially into a second flow path downstream of the gas inlet (3) and/or into a third flow path upstream of the gas outlet (4). The method according to claim 1 or 2, wherein the housing (11) has a T-shaped cross section, wherein the first leg forms a first flow path, and the second leg forms a second flow path, Valve (1), characterized in that the third leg forms a third flow path to the gas outlet (4). 3. A wall according to claim 1 or 2, wherein the flow transfer opening (6) defines the first flow path, as long as the guiding element (5) does not protrude far enough into the second flow path or the third flow path. Valve (1), characterized in that it is closed by means of. 3. The valve according to claim 1 or 2, wherein the valve (1) permits, in a first position, a flow transfer of a gas volume from the first gas inlet (2) and from the second gas inlet (3). It allows the flow transfer of the gas volume to the gas outlet 4, the flow transfer of the gas volume from the first gas inlet 2 is controlled by the open cross-sectional area of the flow transfer opening 6, the second Valve (1), characterized in that the flow transfer of the gas volume from the gas inlet (3) is controlled by the cross-sectional area of the second flow path and/or the third flow path, which is not blocked by the sleeve-like guiding element (5). ). 8. The method according to claim 7, characterized in that at least one sealing means is provided between the wall defining the first flow path and the sleeve-like guiding element (5), preventing it from flowing around the guiding element (5). Valve (1). 3. An actuator (12) arranged outside the housing (11) acts on the guiding element (5) and exerts a force from the actuator (12) to the guiding element (5). The transfer is carried out by means of a guide rod (7), which protrudes through the second and/or third flow path, and the guide element (5) away from the first gas inlet (2). ), characterized in that connected to the valve (1). Valve according to claim 1 or 2, characterized in that the guiding element (5) comprises a guiding structure inside which directs the gas stream flowing to the guiding element (5) to the flow delivery opening (6). One).

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